I'm doing some research on ranking algorithms, and would like to, given a sorted list and some permutation of that list, calculate some distance between the two permutations. For the case of the Levenshtein distance, this corresponds to calculating the distance between a sequence and a sorted copy of that sequence. There is also, for instance, the "inversion distance", a linear-time algorithm of which is detailed here, which I am working on implementing.

Does anyone know of an existing python implementation of the inversion distance, and/or an optimization of the Levenshtein distance? I'm calculating this on a sequence of around 50,000 to 200,000 elements, so O(n^2) is far too slow, but O(n log(n)) or better should be sufficient.

Other metrics for permutation similarity would also be appreciated.

**Edit for people from the future:**

Based on Raymond Hettinger's response; it's not Levenshtein or inversion distance, but rather "gestalt pattern matching" :P

```
from difflib import SequenceMatcher
import random
ratings = [random.gauss(1200, 200) for i in range(100000)]
SequenceMatcher(None, ratings, sorted(ratings)).ratio()
```

runs in ~6 seconds on a terrible desktop.

**Edit2:** If you can coerce your sequence into a permutation of [1 .. n], then a variation of the Manhattan metric is extremely fast and has some interesting results.

```
manhattan = lambda l: sum(abs(a - i) for i, a in enumerate(l)) / (0.5 * len(l) ** 2)
rankings = list(range(100000))
random.shuffle(rankings)
manhattan(rankings) # ~ 0.6665, < 1 second
```

The normalization factor is technically an approximation; it is correct for even sized lists, but should be `(0.5 * (len(l) ** 2 - 1))`

for odd sized lists.

**Edit3:** There are several other algorithms for checking list similarity! The Kendall Tau ranking coefficient and the Spearman ranking coefficient. Implementations of these are available in the SciPy library as `scipy.stats.kendalltau`

and `scipy.stats.rspearman`

, and will return the ranks along with the associated p-values.